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EMDC 1(5096) P3

DRAFT TANZANIA STANDARD TITLE: TOLERANCE LIMITS FOR INDUSTRIAL EFFLUENTS DISCHARGED INTO LAND AND RECEIVING WATER BODIES: OIL AND GAS INDUSTRY

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0. Foreword

Oil and gas are natural products created by the digenesis and thermal maturation of organic material trapped in geological formation within the earth’s surface. They are made up of complex mixtures of thousands of organic substances, which once processed provide a very adaptable commodity from fossil fuels to a variety of petrochemicals. The oil and gas sector is spilt into upstream, mid-stream and downstream activities. The upstream and mid-stream industry includes exploration and production and transfer of oil and gas to the refining or processing facility the downstream industry involves the production (Including refining), distribution and sale of refined hydrocarbon products.

The effluents from oil and gas industries are discharged into land and water. The effluents are varied and complex and the degree of their pollution effect upon the aforementioned systems depend on the constituents of the individual effluent and their corresponding concentrations. The rationale for including permissible limits with regard to physical parameters, organic and inorganic substances as well as microbiological component is based upon their detrimental effect upon human health, aesthetic value, land and aquatic environment.

In the preparation of this Tanzania Standard, considerable assistance was drawn from the following:

a) Report of the Effluent Standards Committee prepared by Effluents Standards Committee (1977)

b) Environmental, Health and Safety (EHS) Guidelines for natural gas processing, April 30, 2007.

In reporting results of tests or analyses made in accordance with this Tanzania Standard, if the final value,

observed or calculated is to be rounded off, it shall be done in accordance with TZS 4 (see clause 2).

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1. Scope This Tanzania standard prescribes the applicable limits to effluents discharged from the oil and gas industry

directly into land and receiving water bodies. The effluent parameters contained herein include physical,

biological and chemical parameters.

This standard covers the oil and gas industry from exploration to production to refining to retail. It includes natural and petroleum gas, fuel oils, petrochemicals, lubricants, petroleum and other by-products.

2. Normative references

The following standards contain provisions which through reference in this text, constitute provisions of this

Tanzania Standard.

All standards are subject to revision, and parties to agreements based on this Tanzania Standard are

required to investigate the possibility of applying the most recent editions of the standards below:

TZS 4: 1979, Rounding off numerical values.

TZS 90: 1980: Water, sewerage and industrial effluents – Glossary of terms

American Public Health Association (APHA), 1989: Standard methods for the examination of water

and wastewater.

APHA Standard methods: 2130 B. Nephelometric method

APHA Standard Methods: 4110 B. Ion chromatography with chemical suppression of eluant

conductivity

APHA standard methods 6410: Liquid-liquid extraction GC/MS method.

APHA standard methods 5520

TZS 861: 2006, Municipal and industrial wastewater test methods.

TZS 861: 2006 Part 10, Municipal and industrial wastewater sampling methods.

TZS 861: Part 1 – Gravimetric method

TZS 861: Part 2 /ISO 10523– Electrometric method

TZS 861 / GC ECD ISO 10301: 1997: Water quality – Determination of highly volatile halogenated

hydrocarbons – Gas chromatographic methods.

TZS 861: Part 5 – Kjeldahl method.

TZS 861: Part 6 / ISO 15681– Colorimetric-ascorbic acid method

TZS 861: Part 7 /ISO 8288– Direct nitrous oxide-Acetylene flame atomic absorption spectrometry

TZS 861: Part 8 / ISO 11885– Manual hydride generation - Atomic absorption spectrometry

TZS 861: Part 9 – Colorimetric method

TZS 861: Part 10 – Cold-vapor atomic absorption spectrometry.

TZS 1403:2016 / GC ECD ISO 6468: 1996: Water quality – Determination of certain organochlorine

insecticides, polychlorinated biphenyls and chlorobenzenes – Gas chromatographic method after

liquid-liquid extraction.

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TZS 1407 / ISO 7875 – 1: 1996, Determination of surfactants – Part 1: Determination of anionic

surfactants by measurement of the methylene blue index (MBAS)

TZS 1929 / ISO 15586: 2003, Water quality – Determination of trace elements using atomic

absorption spectrometer with graphite furnace

ISO 6222: 1999: Water quality – Microbiological methods.

ISO 7887: 1994: Water quality – Examination and determination of colour – Section 3:

Determination of true color using optical instruments.

ISO 6222:1999: Microbiological methods

ISO 7887: 1994: Water quality – Examination and determination of color – Section 3: Determination

of true color using optical instruments.

TZS 1930:2016 / ISO 5815-2: Water quality — Determination of biochemical oxygen demand after

n days (BODn) Part 2: Method for Undiluted samples.

TZS 1132:2016 (REV) / ISO 10530 ISO 10530: Water Quality – Determination of dissolved sulfide

– Photometric method using methylene blue

TZS 1932:2016 / ISO 15705: Water quality — Determination of the chemical oxygen demand index

(ST-COD) — Small-scale sealed-tube method.

3. Terminology

For the purpose of this Tanzania Standard, and the normative references, unless the context specifically indicates otherwise, the following terms and phrases shall have the meanings respectively ascribed to them by this section.

3.1 abandon (a well)

To cease work on a well and seal it off with cement plugs.

3.2 Biochemical Oxygen Demand (BOD)

The mass concentration of dissolved oxygen consumed under specified conditions by the biological

oxidation of organic and/or inorganic matter in wastewater with the prevailing regulations

3.3 Chemical Oxygen Demand (COD)

The mass concentration of oxygen equivalent to the amount of dichromate consumed by dissolved and

suspended matter when a sample of wastewater is treated with that oxidant under defined conditions

3.4 crude oil

Oil produced from a reservoir after any associated gas and/or water has been removed, often simply

referred to as ‘crude’.

3.5 effluents

Liquid waste materials emanating from the operations.

3.6 exploration

The search for oil and gas in the subsurface geological formation, which includes aerial and geophysical

and geochemical surveys, core testing, and drilling of wells.

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3.7 gas processing

The separation of constituents from natural gas for the purpose of making saleable products and also for

treating the residue gas.

3.8 Natural Occurring Radioactive Materials (NORM’S)

Are those materials that contain radioactive elements found naturally in the earth’s environment. Examples

of these radioactive elements are the 238U, 235U, 232Th series and their respective decay daughter, as well

as 40K.

3.9 offshore

Refers to the development of oil fields and natural gas deposits under the ocean.

3.10 oily sludge

Oily waste in the liquid, semi-solid or solid state, which contains or not coarse solids such as scale, sand,

soil and so on. It is usually generated during the cleanup of crude oil and petroleum product tanks, disasters

and other equipment, cleanup of oily water drainage channels and water and oil separators.

3.11 oily waste

Waste mainly composed of a mixture of oil, solids and water, with the occasional presence of other

contaminants.

3.12 onshore

Refers to the development of oil fields and gas deposits on land.

3.13 production

That phase of petroleum activities that deals with bringing the well fluids to the surface and separating them,

and with storing, gauging, and otherwise preparing the product for the pipeline.

3.14 recovery

The total volume of hydrocarbons that has been or is anticipated to be produced from a well or field.

3.15 reservoir rock

Porous and permeable rock, such as sandstone, limestone, or dolomite, containing petroleum within the

small spaces in the rock.

3.16 Technical Enhanced Natural Occurring Radioactive Materials (TE- NORM’S)

Wastes associated with the various industrial activities, with enhanced levels of the natural radioactivity as

a result of industrial process.

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4. Requirements

Disposal of effluents into land and water bodies

Table 4.1: Physical parameters

Parameter Limits Test method

BOD5 at 20 oC mg/L 30 TZS 861: Part 3 – Five-day BOD method (ISO 5815)

COD mg/L 60 TZS 861: Part 4 – Dichromate digestion method

Colour TCU 50 ISO 7887: 1994, Water quality – Examination and

determination of colour – Section 3: Determination of true

color using optical instruments

pH range 6.0 -9.0 TZS 861: Part 2 – Electrometric method (ISO 10523)

Temperature range oC 20-35 See annex A

Temperature change oC ± 3

Total Suspended Solids

(TSS) mg/L

100 TZS 861: Part 1 – Gravimetric method

Turbidity NTU 30 APHA Standard methods: 2130 B. Nephelometric method

Total Dissolved Solids mg/L 1200 ISO 11923

Note;

(i) For on-shore discharge of effluents, in addition to the standards prescribed above, proper

marine outfalls has to be provided to achieve the individual pollutant concentration level in sea

water below their toxicity limits as given below, within a distance of 100 meter from the

discharge point, in order to protect the marine aquatic life.

(ii) For continuous discharge the outfalls shall be beyond the lowest tidal line in order to achieve

maximum mixing.

Table 4.2 – Inorganic parameters

Parameter Limit (mg/L max) Test method

Aluminium 2.0 TZS 861: Part 7 – Direct nitrous oxide-Acetylene flame

atomic absorption spectrometry (ISO 8288)

Arsenic (As) 0.01 TZS 861: Part 8 – Manual hydride generation – Atomic

absorption spectrometry (ISO 11885)

Barium (Ba) 1.5 TZS 861: Part 7 – Direct nitrous oxide-Acetylene flame

atomic absorption spectrometry (ISO 8288)

Barite (BaSO4) Hg: 1 mg/kg dry

weight in stock

barite

TZS 861: Part 10 – Cold-vapor atomic absorption

spectrometry

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Cd: 3 mg/kg dry

weight in stock

barite)

TZS 861: Part 7 – Flame atomic absorption spectrometry

(ISO 8288)

Cadmium (Cd) 0.01 TZS 861: Part 7 – Flame atomic absorption spectrometry

(ISO 8288)

Chromium (total) 1.0 TZS 861: Part 7 – Flame atomic absorption spectrometry

(ISO 8288)

Chromium VI 0.05 TZS 861: Part 9 – Colorimetric method

Chlorides (Cl-) 250 APHA Standard Methods: 4110 B. Ion chromatography

with chemical suppression of eluant conductivity

Cobalt (Co) 1.0 TZS 861: Part 7 – Flame atomic absorption spectrometry

(ISO 8288)

Copper (Cu) 0.5 TZS 861: Part 7 – Flame atomic absorption spectrometry

(ISO 8288)

Fluorides (F-) 4 APHA standard methods: 4110 B. Ion chromatography

with chemical suppression of eluant conductivity

Iron 5.0 TZS 861: Part 7 – Flame atomic absorption spectrometry

(ISO 8288)

Lead (Pb) 0.01 TZS 861: Part 7 – Flame atomic absorption spectrometry

(ISO 8288)

Manganese 5.0 TZS 861: Part 7 – Flame atomic absorption spectrometry

(ISO 8288)

Mercury (Hg) 0.001 TZS 861: Part 10 – Cold-vapor atomic absorption

spectrometry

Nickel (Ni) 0.5 TZS 861: Part 7 – Flame atomic absorption spectrometry

(ISO 8288)

Nitrates (NO3-) 45 APHA standard methods: 4110 B. Ion chromatography

with chemical suppression of effluent conductivity

Nitrites 1.0 ISO 6777

Total Nitrogen 10 ISO 5663

Ammonium nitrogen 5 ISO 11905

Phosphorus Total (as

P) 5 TZS 861: Part 6 – Colorimetric-ascorbic acid method (ISO

15681)

Selenium (Se) 0.02 TZS 861: Part 8 – Manual hydride generation – Atomic

absorption spectrometry (ISO 11885)

Silver (Ag) 0.1 ISO 15586: 2003, Water quality – Determination of trace

elements using atomic absorption spectrometer with

graphite furnace

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Sulphate (SO42-) 500 APHA Standard Methods: 4110 B. Ion chromatography

with chemical suppression of eluant conductivity

Sulphides (S-) 1 APHA standard methods: 4110 B. Ion chromatography

with chemical suppression of eluant conductivity

Tin (Sn) 2.0 TZS 861: Part 7 – Flame atomic absorption spectrometry

(ISO 8288)

Total Kjeldahl Nitrogen

(as N) 15 TZS 861: Part 5 – Kjeldahl method

Vanadium 1.0 ISO 15586: 2003, Water quality – Determination of trace

elements using atomic absorption spectrometer with

graphite furnace

Zinc (Zn) 5.0 TZS 861: Part 7 – Flame atomic absorption spectrometry

Cyanide 0.05 ISO 6703

Total residue chlorine 0.2 ISO 7393-2

Table 4.3 – Organic parameters

Parameter Limit (mg/L max) Test method

1, 1, 2 –Trichloroethane 0.06 GC ECD (ISO 10301: 1997, Water quality –

Determination of highly volatile halogenated

hydrocarbons – Gas chromatographic

methods)

1,1,1 – Trichloroethane 3.0 GC ECD (ISO 10301: 1997, Water quality –

Determination of highly volatile halogenated

hydrocarbons – Gas chromatographic

methods)

1,2 – Dichloroethylene

0.2 GC ECD (ISO 10301: 1997, Water quality –

Determination of highly volatile halogenated

hydrocarbons – Gas chromatographic

methods)

1,2 – Dichloroethane 0.04 GC ECD (ISO 10301: 1997, Water quality –

Determination of highly volatile halogenated

hydrocarbons – Gas chromatographic

methods)

1,3 – Dichloropropene 0.2 GC ECD (ISO 10301: 1997, Water quality –

Determination of highly volatile halogenated

hydrocarbons – Gas chromatographic

methods)

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Parameter Limit (mg/L max) Test method

Alkyl benzene sulfonate (ABS) 0 ISO 7875 – 1: 1996, Determination of

surfactants – Part 1: Determination of

anionic surfactants by measurement of the

methylene blue index (MBAS)

Aromatic nitrogen containing compounds (e.g., aromatic amines)

0.001 APHA standard methods 6410: Liquid-liquid

extraction GC/MS method

cis-1, 2 – Dichloroethylene 0.4 GC ECD (ISO 10301: 1997, Water quality –

Determination of highly volatile halogenated

hydrocarbons – Gas chromatographic

methods)

Dichloromethane 0.2 GC ECD (ISO 10301: 1997, Water quality –

Determination of highly volatile halogenated

hydrocarbons – Gas chromatographic

methods)

Oil and grease (fatty maters

and hydrocarbons)

10 APHA standard methods 5520

Phenols 0.002 GC ECD (ISO 6468: 1996, Water quality –

Determination of certain organochlorine

insecticides, polychlorinated biphenyls and

chlorobenzenes – Gas chromatographic

method after liquid-liquid extraction)

Tetrachloroethylene 0.1 GC ECD (ISO 10301: 1997, Water quality –

Determination of highly volatile halogenated

hydrocarbons – Gas chromatographic

methods)

Tetrachloromethane 0.02 GC ECD (ISO 10301: 1997, Water quality –

Determination of highly volatile halogenated

hydrocarbons – Gas chromatographic

methods)

Trichloroethylene 0.3 GC ECD (ISO 10301: 1997, Water quality –

Determination of highly volatile halogenated

hydrocarbons – Gas chromatographic

methods)

Toluene 1 GC/MS (USEPA Method 1624 and 624)

Styrene 0.1 GC/MS

Benzene 0.05 GC/MS (USEPA Method 1624 and 624)

Chlorobenzene 0.1 GC/MS

Xylenes (Total) 10 GC/MS

PAHS (Benzo (a) Pyrene 0.002 GC/MS

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Parameter Limit (mg/L max) Test method

Total Organic Carbon (TOC) 1000 UV Oxidation/ IR

PCBs 0.003 TZS 1403:2016 / ISO 6468

polycyclic aromatic

hydrocarbons (PAH) and alkyl

phenols (AP)

0.0001 milligrams

per liter (mg/L)

Gas chromatography (GC/MS or HPLC)

(with a packed column)

Table 4.4- Natural Occurring Radioactive Materials (NORM’S)

Parameter Limit (Bq/g) or (Bq/l) Detection Methods 238U 1

Powder X -ray diffractometer, FT-IR spectrometry, X -ray fluorescence (XRF) spectrometer

-ray spectrometer equipped with a High Purity Germanium (HPGe) detector.

235U 1 232Th 1 226Ra 10 222Rn 10 228Ra 10 224 Ra 10 208Tl 10

Note:

For onshore disposal of the NORM permissible limits is < 50Bq/g but it should be in unpopulated and desert

areas.

Table 4.5 – Microbiological parameters

Parameter Limit (counts/100ml) Test method

Total coliform organisms 10,000 ISO 6222:1999, Microbiological

methods

E- coli 400 ISO 6222:1999, Microbiological

methods

Fecal Coliform 1,000 ISO 6222:1999, Microbiological

methods

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5 Compliance with specified effluent limits

Discharging of wastewater in water bodies should ensure that

a) Effluent quality described in table 1 is achieved consistently;

b) Monitoring should be done by sampling in accordance with

TZS 861(Part 10): 2006, – Sampling methods;

c) Effluent shall be treated onsite prior to discharge, dilution is not treatment;

d) Effluents are not discharged in close proximity to water supply sources and recreational areas.

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Annex A

Depth temperature measurement

Depth temperature required for limnological studies may be measured with a reversing thermometer,

thermophone, or themistor. The thermistor is most convenient and accurate; however, higher cost may

preclude its use. Calibrate any temperature measurement devices with TBS–certified thermometer before

field use. Make readings with the thermometer or device immersed in water long enough to permit complete

equilibration. Report results to the nearest 0.1 or 1.0oC, depending on need.

The thermometer commonly used for depth measurements is of the reversing type. It often is mounted on

the sample collection apparatus so that a water sample may be obtained simultaneously. Correct readings

of reversing thermometers for changes due to differences between temperature at reversal and temperature

at time of reading. Calculate as follows:

Where:

T correction to be added algebraically to uncorrected reading,

T’ uncorrected reading at reversal t temperature at which thermometer is read Vo volume, of small bulb end of capillary up to 0oC graduation K constant depending on relative thermal expansion of mercury and glass (usual value of

K = 6100), and L calibration correction of thermometer depending on T’

If series observations are made it is convenient to prepare graphs for a thermometer to obtain T from any

values of T’ and t.

L

K

VTtT

K

VTtTT oo

''1

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